to match the vibration frequency of BPhT
atnm≃32.4 THz.
When a pump laser tuned at 405 THz (740 nm)
is focused on the sample (Fig. 2A), the para-
metric interaction with the molecular vibra-
tions generates Raman sidebands at lower
(Stokes) and higher (anti-Stokes) frequencies
(Fig. 2B). The giant enhancement factor described
above makes it possible to detect the Raman
signal from few hundred molecules, as esti-
mated from the VIS mode area (fig. S12) and
molecular layer density (see the supplemen-
tary materials, section 1.6). Without IR beam
incident on the device (black solid line in
Fig. 2B), the Stokes signal is dominated by
spontaneous emission of phonon-photon pairs,
whereas the anti-Stokes signal originates from
the upconversion of thermal vibrations ( 31 ).
At room temperature (T= 25°C), the thermal
occupancy of the vibrational mode atnm=
32 THz isnth¼ exphnm
kBT
1 1
≃ 5 : 8 � 10 ^3wherehandkBare Planck’s and Boltzman’s
constants, respectively.
When the IR beam from a quantum cascade
laser was focused through the Si substrate
onto the back side of the device (Fig. 2A), we
observed two new peaks at the correspond-
ing Raman shift on the Stokes and anti-Stokes
sidebands (green line in Fig. 2, B and C), the
linewidthofwhichwasmuchnarrowerthanthe
natural linewidth of the spontaneous Raman
scattering peaks (Fig. 2, D and E). Altogether,these observations are compatible with a co-
herent upconversion process as pictured in
Fig. 1D. As we tuned the frequency of the
incoming field, the upconverted signal shifted
accordingly, and its measured linewidth was
found to be limited by that of our spectrometer,
with a value of 7 GHz or 0.23 cm–^1 (compare
fig. S8), which is well below that of single-
molecule Raman linewidths typically observed
at room temperature (see the supplementary
materials, section 2.2). The relative conversion
efficiency versus detuning is plotted in fig. S7
and confirms that upconversion is assisted by
the vibrational mode.
We interpret these results as being the mani-
festation of optomechanical transduction, in
which a collective molecular vibrational mode is
resonantly driven by the nanocavity-enhanced
incoming IR field. Because of the ~50 times
larger mode volume in the IR versus VIS
domain (compare Fig. 1, G to J, and fig. S12),
many of the molecules covering the groove
may be vibrationally excited yet remain silent
in Raman scattering. In the following, we
consider only the subset of molecules that
are in the region where IR and VIS near
fields strongly overlap, which contains a few
hundred molecules at most (see calculation in
the supplementary materials, section 1.6). We
can describe their collective vibrational state
by a displaced thermal state with a coherent
amplitudeaand a corresponding coherent
occupancyncoh=|a|^2. This coherent, IR-driven
oscillation is mapped onto the Raman side-
bands of the pump laser, where the IR signal
can be analyzed and detected using Si-based
detectors. Without IR drive, the Stokes and
anti-Stokes photon rates are proportional to
1+nthandnth, respectively; with IR drive,
these rates become proportional to 1þnthþ
nScohandnaSthþncoh, respectively. We added
the superscripts“S”and“aS”to highlight
that the observed value ofncohdepends on
the overlap between Raman scattered and IR
near fields. Knowingnth, we can extractn
S;aS
coh
from the measured Raman count rate with
and without IR drive or, equivalently, from
the area subtended by the sharp upconverted
peak versus that of the broad spontaneous
or thermal emission. Moreover, under the ap-
proximationnth≪1, the Stokes sideband offers
a self-calibrated measurement ofnScoh. For
most nanocavities, we found 0: 1 ≤nScoh≤ 0 : 5
for 500 to 600mW IR power (compare table
S2), corresponding to 20 to 24mW/mm^2 IR
power density at the spot's center (fig. S17).
This figure is compatible with an enhance-
ment of IR absorption cross section per mole-
cule by more than five orders of magnitude, as
predicted from field enhancement simulations
and detailed in the supplementary materials,
section 1.6.
When varying the power of the pump laser
at 740 nm, we observed a linear dependence1266 3 DECEMBER 2021•VOL 374 ISSUE 6572 science.orgSCIENCE
Fig. 3. Dependence of thermal and upconverted signals on IR and VIS powers.(A) Gray and green
circles represent the rates of thermal (kaSth) and upconverted (kSFG; for 600mW IR power) anti-Stokes
photons, respectively, as a function of VIS pump power (tuned at 740 nm). The ratio of thermal
anti-Stokes to Stokes signals (without IR input) is plotted as orange squares. Solid lines are linear
functions; the dashed line is a constant. The blue shaded area denotes the power range used in other
upconversion measurements. (B) IR-driven anti-Stokes coherent occupancynaScoh(green circles) extracted
from the sharp peak area [compare with (C)], together with the thermal occupancy inferred from
the area of the broad anti-Stokes emission (gray circles) as a function of incident IR power (VIS pump
power 10mW, tuned at 740 nm). The green line is a linear fit; the dashed line is a constant. To
convert peak area to phonon occupancy, we assumed that the molecules were at 25°C without IR input.
(C) Detection of submicrowatt IR signals using high-resolution spectroscopy on the anti-Stokes
sideband. Acquisition time was 600 s.
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